Auxiliary light mount assembly for tubular bumpers

ABSTRACT

A clamp assembly adapted for attachment to a tubular beam includes first and second grips, with each grip having and at least four curved fingers projecting radially from the central portion and curving generally in the same direction to respective distal ends. The grips are secured together in a complementary relationship with the distal ends of the fingers of the first grip aligning with the distal ends of the fingers of the second grip to define a first generally cylindrical aperture extending through the fingers in a first direction and a second generally cylindrical aperture extending through the fingers in a second direction. The first cylindrical aperture has a diameter that substantially corresponds to the diameter of the tubular beam to which the clamp assembly is to be clamped. The clamp assembly generally includes a flange for attaching auxiliary equipment to the clamp assembly.

TECHNICAL FIELD

This disclosure relates generally to clamp assemblies for mounting itemsof equipment to tubular beams, and in particular to clamp assemblies foradjustably coupling auxiliary lights to the tubular bumpers and rollbars of off-road vehicles.

BACKGROUND

Tubular bumpers and roll bars are often mounted to jeeps, trucks, dunebuggies, sand rails, and other type of off-road vehicles to shield thevehicle from external hazards and to protect the vehicle and itsoccupants in the event of an accident or roll-over. Due to theirpositions at the front or top of the vehicle, these tubular beams canalso offer advantageous locations for auxiliary lighting that canprovide increased illumination of the area immediately surrounding thevehicle at night or in adverse weather conditions. As a result, anindustry has developed to provide a variety of mounting systems forauxiliary lighting fixtures such as flood lights, spot lights, foglights and the like to the off-road vehicle aftermarket.

However, the different manufacturers of tubular bumpers and roll barshave generally provided these protective structures in their ownpreferred designs, sizes and customized configurations, that in turnrequire auxiliary equipment mounting systems that have been custom fitfor each tubular beam product. Thus, vehicle owners and other purchasersof auxiliary equipment have been compelled either to purchase thesecustomized mounting systems at a premium price, to mount their auxiliaryequipment at alternative less-desirable locations, or to seek otherarrangements.

Consequently, a need exists for a mounting system or clamp assembly forauxiliary equipment that is adaptable to be used with a plurality ofdifferently-sized tubular beams, and that can be applied by vehicleowners and other end users to mount their preferred auxiliary equipmentproducts, such as after-market auxiliary lighting fixtures, at thedesired location on their tubular bumpers or roll bars. It is towardsuch a mounting system or clamp assembly that the present disclosure isdirected.

SUMMARY

Briefly described, one embodiment of the present disclosure includes amounting system or clamp assembly that is configured to be clampedaround a tubular beam to provide a mounting location for an auxiliarycomponent. The clamp assembly includes a first grip having a centralportion and at least four curved fingers projecting radially from thecentral portion and curving generally in the same direction torespective distal ends, and a second grip also having a central portionand at least four curved fingers projecting radially from the centralportion and curving generally in the same direction to respective distalends. The clamp assembly further includes a fastener for securing thefirst and second grips together in a complementary relationship with thedistal ends of the fingers of the first grip aligning with the distalends of the fingers of the second grip. When secured together, the gripsdefine a first generally cylindrical aperture extending through thefingers in a first direction and a second generally cylindrical apertureextending through the fingers in a second direction. The firstcylindrical aperture has a diameter that substantially corresponds tothe diameter of the tubular beam to which the clamp assembly is to beclamped. In addition, a flange can be mounted to one of the grips andconfigured to receive an auxiliary component.

Another embodiment of the clamp assembly is adapted for attachment to aplurality of differently-sized tubular beams. The clamp assemblyincludes first and second grips, with each grip having a central portiondefining a first plane and a plurality of angularly-spaced fingerscurving radially outward and out-of-plane from the central portion todistal ends defining a second plane that is spaced from the first plane.Each finger includes an inside face with two curved surfaces separatedby a center edge, with the curved surfaces extending in oppositedirections to the inside faces of adjacent fingers to form a pluralityof partial cylindrical surfaces. When the distal ends of the first andsecond grips are coupled together, different sets of partial cylindricalsurfaces align to form multiple generally cylindrical split apertures,with each being adapted to clamp around differently-sized tubular beams.The clamp assembly also includes a flange for attaching auxiliaryequipment such as a light fixture to the clamp assembly.

Another embodiment of the clamp assembly includes a first grip and asecond grip, with each of the first and second grips comprising acentral portion having a center axis and an outer face defining a firstplane perpendicular to the center axis, and a plurality ofangularly-spaced fingers curving radially outward and out-of-plane fromthe central portion to a plurality of distal ends that define a secondplane that is spaced from and parallel to the first plane, and with eachof the distal ends including provision for a fastener. The inside faceof each finger further includes a first curved surface and a secondcurved surface that are separated by a center edge. Each curved surfaceextends in opposite directions across an inside face of the centralportion to the curved surfaces of adjacent opposing fingers. This formsa first partial cylindrical surface and a second partial cylindricalsurface that intersect at the center axis of the central portions. Thesets of complimentary first and second partial cylindrical surfacesalign to form first and second generally cylindrical split apertures.Each split aperture is configured to clamp around and secure the clampassembly to at least one of a plurality of differently-sized tubularbeams.

The clamp assembly can also include a plurality of fasteners or fastenerassemblies extending between and coupling the distal ends of the fingersof the first and second grips. A flange may be coupled to one of thefirst and second grips that is configured to receive and coupleauxiliary equipment to the clamp assembly.

Another embodiment of the present disclosure comprises a clamp assemblythat is configured to be clamped around a tubular beam to provide amounting location for an auxiliary component. The clamp assemblyincludes a first grip having an inner face with at least four curvedsurfaces separated by center edges, with the center edges of the firstgrip extending radially from a center axis and curving generally in thesame direction toward respective attachment portions of the first grip,as well as a second grip also having an inner face with at least fourcurved surfaces separated by center edges, and with the center edges ofthe second grip extending radially from a center axis and curvinggenerally in the same direction toward respective attachment portions ofthe second grip. The clamp assembly further includes a fastener forsecuring the first and second grips together in a complementaryrelationship with the attachment portions of the first grip aligningwith the attachment portions of the second grip. When secured together,the curved surfaces define a first generally cylindrical apertureextending through the clamp assembly in a first direction and a secondgenerally cylindrical aperture extending through the clamp in a seconddirection. The first cylindrical aperture has a diameter thatsubstantially corresponds to the diameter of the tubular beam to whichthe clamp assembly is to be clamped. In addition, a flange can bemounted to one of the grips and configured to receive an auxiliarycomponent.

Another embodiment of the present disclosure comprises a method ofmoving a mounting system or clamp assembly between a plurality ofdifferently-sized tubular beams. The method includes uncoupling a pairof grips that are clamped around a first tubular beam having a firstsize, with each of the grips including a central portion and at leastfour fingers curving radially from the central portion and curvinggenerally in the same direction to respective distal ends, with eachfinger including an inside face with two curved surfaces separated by acenter edge, and with the curved surfaces extending in oppositedirections to the inside faces of adjacent fingers to form a pluralityof partial cylindrical surfaces. A first set of partial cylindricalsurfaces aligns to form a first generally cylindrical split aperturethat is sized and shaped to receive the first tubular beam when thedistal ends of the grips are coupled together.

The method also includes removing the grips from around the firsttubular beam, moving the clamp assembly to a second tubular beam havinga second size that is different from the first size, positioning asecond set of partial cylindrical surfaces of the grips around thesecond tubular beam, with the second set of partial cylindrical surfacesaligning to form a second generally cylindrical split aperture that issized and shaped to receive the second tubular beam. The method furtherincludes coupling together the distal ends of the grips to clamp andsecure the clamp assembly to the second tubular beam.

The invention will be better understood upon review of the detaileddescription set forth below taken in conjunction with the accompanyingdrawing figures, which are briefly described as follows.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front perspective view of a clamp assembly attached to atubular beam, in accordance with a representative embodiment.

FIG. 2 is an exploded front perspective view of the clamp assembly ofFIG. 1.

FIG. 3 is an exploded rear perspective view of the clamp assembly ofFIG. 1.

FIG. 4 is a perspective, cross-sectional view of the clamp assembly astaken from Section Line 5-5 in FIG. 1.

FIGS. 5A and 5B are views of the interior faces of the first and secondgrips of the clamp assembly of FIG. 1.

FIG. 6 is a side view of the clamp assembly and tubular beam of FIG. 1.

FIGS. 7 and 8 are a perspective view and a top view, respectively, ofthe clamp assembly of FIG. 1 attached to another differently-sizedtubular beam.

FIGS. 9 and 10 are a perspective view and a top view, respectively, ofthe clamp assembly of FIG. 1 attached to yet another differently-sizedtubular beam.

Those skilled in the art will appreciate and understand that, accordingto common practice, various features of the drawings discussed below arenot necessarily drawn to scale, and that dimensions of various featuresand elements of the drawings may be expanded or reduced to more clearlyillustrate the embodiments of the present invention described herein.

DETAILED DESCRIPTION

Illustrated in FIGS. 1-10 is a representative embodiment of a mountingsystem or clamp assembly for adjustably coupling an auxiliary lightfixture or other equipment item to one of a plurality ofdifferently-sized tubular beams, and in particular to various sizes oftubular bumpers and roll bars used with off-road vehicles. As describedin more detail below, the clamp assembly of the present disclosureprovides several significant advantages and benefits over other devicesand methods for coupling auxiliary light fixtures or equipment items tothe differently-sized tubular beams. The recited advantages are notmeant to be limiting in any way, however, as one skilled in the art willappreciate that other advantages may also be realized upon practicingthe present disclosure. It is also to be appreciated that the clampassembly disclosed herein may not be limited to uses relating to thetubular bumpers and roll bars of off-road vehicles, and that other usesand applications are also possible and may be considered to fall withinthe scope of the present disclosure.

As used herein, “tubular beam” refers to a structural member, such as arod, a shaft, a pole, a rail, and at the like, having an outer surfacearound which the clamp assembly may be clamped. The tubular beam maygenerally be round and hollow and comprising a cylindrical cross-sectionsimilar to that shown in the drawings. However, in some aspects thetubular beam may also be solid or formed with a non-roundcross-sectional profile, including but not limited to an oval or apolygonal cross-sectional profile. In addition, the tubular beam may bealigned in any direction relative, including horizontal, vertical, orinclined orientations.

Referring now in more detail to the drawing figures, wherein like partsare identified with like reference numerals throughout the severalviews, FIG. 1 is a perspective front view of a clamp assembly 10 thatcan be removably attached to a tubular beam 92 so as to couple anauxiliary light fixture (not shown) or similar item of auxiliaryequipment to the tubular beam 92. In some applications, the auxiliarylight fixture may comprises a spot light, a flood light, a fog light,and the like. For other applications, a non-exhaustive list of auxiliaryequipment items that may also be mounted to the tubular beam of theclamp assembly includes, but is not limited to, an antennae, a GPSreceiver, a horn, a camera, a sensor, a photovoltaic solar panel, an LEDdisplay, and the like.

In some applications, the tubular beam 92 can be the tubular bumper orroll bar of an off-road vehicle such as a jeep, a truck, a dune buggy, asand rail, and the like. The clamp assembly 10 is not limited toattachment to just one particular size of tubular beam, but is adaptedfor attachment along the length of any one of a plurality ofdifferently-sized tubular beams such as those commonly be found in theoff-road vehicle industry. In addition, the clamp assembly 10 generallyincludes an angularly-adjustable flange 50 that provides increasedflexibility for positioning the auxiliary light fixture or equipmentitem in a variety of positions and angular orientations relative to thelong axis of the tubular beam 92.

As shown in the exploded perspective views of FIGS. 2-3, the clampassembly 10 generally includes a first grip 20 and a second grip 30.Each of the first and second grips 20, 30 comprise central portions 22,32 and a plurality of fingers 26, 36 that projecting radially outwardand at angularly-spaced intervals from their respective central portions22, 32. Each of the central portions 22, 32 has a center axis 21, 31,and an outer face 24, 34 that defines a first plane 25, 35 (FIG. 6) thatis perpendicular to its respective center axis 21, 31. In addition, eachof the fingers 26, 36 curves out-of-plane and away from the first plane25, 35 of their respective central portion 22, 32 as they extendradially outward from the central portions, to terminate in distal ends28, 38 having substantially-planar end surfaces 27, 37. The plurality ofsubstantially-planar end surfaces 27, 37 of each of the first and secondgrips 20, 30 align together to define second planes 29, 39 (also FIG. 6)that are spaced from and parallel to their respective first planes 25,35.

Each of the distal ends 28, 28 of the fingers 26, 36 of the first andsecond grips 20, 30 also include provision 60 for a fastener 70 thatallows the first and second grips 20, 30 to be coupled together in amirrored or facing relationship. In the illustrated embodiment 10 of theclamp assembly, the fasteners 70 can be machine screws 72 having athreaded portion 74 and a head portion 76, as well as one or more jamnuts 78 that are rotatably threaded onto the threaded portions 74 of themachine screws 72. It is to be appreciated, however, that other types offasteners may also be used to coupled together the distal ends 28, 38 ofthe first and second grips 20, 30 in the above-described facingrelationship, and may also be considered to fall with in the scope ofthe present disclosure.

Also shown in FIGS. 2-3 is the angularly-adjustable flange 50 that iscoupled to the second grip 30. In the illustrated embodiment 10, theflange is coupled against the outer face 34 of the second grip 30 thatdefines the bracket's first plane 35 (FIG. 6) and includes a baseportion 52 with a thru-hole 53 that is sized and shaped to receive thehead of a mounting screw 59. The threaded portion of the mounting screw59 extends through the thru-hole 53 of the base portion 52 to threadablyengage with a threaded hole 47 formed through the central portion 32 ofthe grip 30. As shown, the base portion 52 can also include engagementstructures, such as posts 54, that interface with complimentaryengagement structures, such as sockets 48, that upon engagement hold andsecure the flange 50 to the grip 30 without rotation. The base portion52 may also be provided with a raised area 55 that fits within acomplimentary recess 49 formed into the grip 30, with the lines ofcontact between the perimeter of the raised area 55 and the sidesurfaces of the recess 49 further serving to hold and secure the flange50 to the grip 30.

In one aspect, the engagement structures 54, 48 can be angularly spacedat equal angular intervals around the thru-hole 53 and the threaded hole47. As such, the flange 50 can be rotated or indexed relative to thegrip 30 by removing the mounting screw 59, separating the flange 50 fromthe grip 30, rotating the flange relative to the grip, re-engaging thebase portion 52 of the flange 50 with the outer face 34 of the grip 30,and re-engaging the mounting screw 59 within the threaded hole 47. Withregard to the illustrated embodiment of the clamp assembly 10, theangular spacing between the engagement structures 54, 48 and the shapeof the raised area 55 and its complimentary recess 49 provide for theindexed rotation of the flange 50 at ninety-degree intervals.Nevertheless, the skilled artisan will appreciate that the size, shapeand angular spacing between the engagement structures 54, 48 and betweenthe raised area 55 and the recess 49 can be varied to provide differentindexing intervals. This includes smaller rotation intervals that allowfor the flange to extend at oblique angles relative to the longitudinalaxis of the tubular beam.

The flange 50 can further include a flange portion 56 that extendslaterally from one end of the base portion 52, and includes a contactface 58 and another thru-hole 57. The flange portion 56 can generallyprovide a base surface or structure for the mounting apparatus of anauxiliary light fixture (not shown, but known to one of skill in theart) or other equipment item, as described above.

Also shown in FIGS. 2-3 is a logo plate 80 that can be mounted to thecentral portion 22 of the first grip 20 to provide a finished andcustomizable look to the clamp assembly 10. The logo plate 80 can beangularly adjustable and aligned to the outer face 24 of the centralportion 22 that defines the first plane 25 (FIG. 6) of the first grip20, and in a manner similar to the way the flange 50 is angularlyadjustable and aligned with the outer face 34 of the second grip 30using engagement structures and/or outer shape of the logo plate and theshape of the complimentary recess formed into the central portion 22 ofthe first grip 20. Indeed, in one aspect the first grip 20 and secondgrip 30 can be configured so that logo plate 80 and the flange 50 andreversible and interchangeable between the two grips, in which case theprimary difference between the two grip can be the fastening provisions60 formed into the distal ends 28, 38 of the fingers 26, 36.

FIG. 4 is a perspective, cross-sectional view of the representativeembodiment of the fastener 70, or machine screw 72, and the provisions60 for the machine screw 72 that have been formed into the distal ends28, 38 of the fingers 26, 36. For instance, each of the distal ends 28of the fingers 26 of the first grip 20 can included a threaded hole 62formed into the substantially planar surface 27, with the threaded holebeing adapted to engage with the threaded end 74 of the machine screw72. The threaded hole 62 can be closed (as shown), or can extend all theway through the finger 26.

A non-threaded rabbet hole 64 can be formed into the distal ends 38 ofthe fingers 36 of the second grip 30. The rabbet hole 64 can have anouter passage 67 sized to receive the head portion 76 of the machinescrew 72 and an inner passage 65 sized to receive only the treadedportion 74, and with an interior rabbet surface 66 that abuts the headportion 76 of the machine screw. In some aspects, a gasket member orwasher 68 can be installed between the head portion 76 of the machinescrew 72 and the rabbet surface 66 to provide a level of compliance ortensioning pre-load when the two grips 20, 30 are fastened togetheraround the tubular beam 92. The gasket member or washer 68 can be madefrom metal or from a compliant material such as rubber or a syntheticelastomer. If metal, the washer 68 may be cut and formed into aspring-type lock washer to provide the desired compliance or fasteningpre-load.

To install the machine screw 72 to the second grip 30, the washer 68 canbe moved over the threaded portion 74 to contact the head portion 76,and then the machine screw can be inserted through the inner passage 65of the rabbet hole 64 until the washer 68 contacts the rabbet surface 66and the threaded portion 74 projects out of the planar surface 37 of thefinger 36. One or more jam nuts 78 can then be threaded onto thethreaded portion 74, leaving enough open thread for the machine screw 72to engage with the threaded hole 62 when the two grips are assemblyaround the tubular beam. The machine screw 72 can then be rotated toengage the threads and draw the screw into the threaded hole 62 untilthe head portion 76 presses the washer 68 against the rabbet surface 66to firmly clamp the two grips 20, 30 around the tubular beam. At thispoint the jam nuts 78 can be backed out to bear against one or both ofthe substantially planar surfaces 27, 37 to prevent any further rotationof the machine screw 72 relative to the threaded hole 62, therebylocking the clamp assembly 10 to the tubular beam.

Of course, it is not required that the threaded holes 62 be formed intothe fingers 26 of the first grip 20 or that the rabbet holes 64 beformed into the fingers 36 of the second grip 30. It is to beappreciated, moreover, that the fastening provisions 60 for thefasteners 70 can be reversed or altered in a variety of ways known tothose of skill in the art while continuing to fall within the scope ofthe present disclosure. In addition, the first and second grips can belocked together using fasteners other than threaded machine screws. Forexample, a mechanical latch may be used to draw the distal ends of thetwo sets of fingers together and to tighten the grips around a tubularbeam without the use of threaded machine screws or bolts.

FIGS. 5A-5B are views of the interior faces 23, 33 of the first andsecond grips 20, 30 of the clamp assembly 10, and provide additionalperspective of the structural relationship between the central portions22, 32, the center axes 21, 31, and the plurality of fingers 26, 36 thatproject radially outward from their respective central portions 22, 32at angularly-spaced intervals. FIGS. 5A-5B also illustrate thesubstantially-planar end surfaces 27, 37 that can be located at thedistal ends 28, 38 of the fingers 26, 36, as well as the location of theprovisions for the fasteners 70 across the substantially-planar endsurfaces 27, 37.

As can be seen, the inside face of each finger 26, 36 can comprise afirst curved surface 40 and a second curved surface 42 separated by acenter edge 45 that extends radially, or lengthwise, along the insideface of the finger 26, 36 from central portion 22, 32 to the distal ends27, 37. For each finger 26, 36, the curved surfaces can extend laterallyor angularly in opposite directions across the inside face of thecentral portion 22, 32 to the curved surfaces of the adjacent opposingfingers. As shown in the drawings, this arrangement can subdivide theinterior faces 23, 33 of both grips 20, 30 into two opposed first curvedsurfaces 40 and two opposed second curve surfaces 42. With each grip,the two opposed first curved surfaces 40 can align to define a firstpartial cylindrical surface 41, and the two opposed second curvedsurfaces 42 can similarly align to define a second partial cylindricalsurface 43. The first and second partial cylindrical surfaces 41, 42 canbe formed with different diameters or radii of curvature for thepurposes discussed in more detail below.

When the first and second grips 20, 30 are coupled together to assemblethe clamp assembly 10, the set of first partial cylindrical surfaces 41can align to define a first generally cylindrical split aperture 44 thatis sized and shaped to receive a tubular beam 92 of a first size, asillustrated in FIG. 6. The split aperture 44 can include a first gap 82between the substantially-planar end surfaces 27 of the first grip 20and the substantially-planar end surfaces 37 of the second grip 30, sothat the second planes 29, 39 defined by the plurality of end surfaces27, 37 of the first and second grips 20, 30, respectively, are spacedfrom each other. In one aspect, the second planes 29, 39 can alignsubstantially parallel with each other upon assembly so that theclamping assembly 10 provides a symmetric and uniform grip on thetubular beam. In another aspect (not shown), the planes 29, 39 may benon-parallel as one of both of the grips 20, 30 becomes cocked ormisaligned during the assembly process of tightening each of the fourfasteners 70. Depending on the tolerances provided by the fasteners 70and the fastening provisions 60 formed into the distal ends of thefingers, however, the arc length of the partial cylindrical surfaces 41can be sufficient to continue to secure the clamping assembly 10 to thetubular beam 92, even with substantial misalignment.

When the first and second grips 20, 30 are coupled together to assemblethe clamp assembly 10, as discussed above, the set of second partialcylindrical surfaces 43 can also align to form a second generallycylindrical split aperture 46 that is configured to receive a tubularbeam 94 of a second size that is different than the first size, as shownin FIGS. 7-8. With the grips 20, 30 each having four fingers 26, 36, andwith the inside face of each finger having a first curved surface 40 anda second curved surface 42 separated by a center edge 45 that extendsradially, or lengthwise, along the inside face of the finger 26, 36, theresulting first partial cylindrical surfaces 41 and second partialcylindrical surfaces 43 can be orthogonal to each other, so that thefirst split aperture 44 and the second split aperture 46 are alsoorthogonal to one another.

In other embodiments, however, it is contemplated that each of the gripscan have more than four fingers, so that the curved surfaces formed intothe inside faces of the fingers can align to form three or more partialcylindrical surfaces that are non-orthogonally aligned, as well as threeor more non-orthogonally aligned, generally cylindrical split apertureshaving different diameters.

In addition, in some aspects the first curved surfaces and the secondcurved surfaces that comprise the inside faces of the fingers may not beformed on a constant radius, and instead may be formed with a variableradius that results in a split aperture having an oval or othernon-round curved shape. Furthermore, the first curved surfaces and thesecond curved surfaces may not be smoothly curved along their extentsfrom the central portions to the distal ends of the grip, and mayinstead comprise a plurality of faceted planar surfaces that join ormerge together at one or more oblique angles, with the oblique anglesbeing ninety degrees or greater. In this way, the split apertures formedby the coupled first and second grips can be sized and shaped to beassembled around non-round tubular beams having oval, polygonal, or evensquare cross-sections, and the like.

It is also contemplated that in yet another embodiment of the clampassembly that the two grips may not include fingers. Instead, each gripcan comprise an inner face with at least four curved surfaces separatedby center edges, with the center edges of the first grip extendingradially from the center axis and curving generally in the samedirection toward respective attachment portions formed into the firstgrip, and with the center edges of the second grip extending radiallyfrom the center axis and curving generally in the same direction towardrespective attachment portions formed into the second grip. In oneaspect, the attachment portions may be flats or recesses formed into thecorners of each grip. As with the embodiments described above, theattachment portions can also include provision for fasteners so that thefasteners can secure the first and second grips together in acomplementary relationship when the attachment portions of the firstgrip are aligned with the attachment portions of the second grip.Likewise, the curved surfaces formed into the inner faces of the gripscan define a first generally cylindrical aperture extending through theclamp assembly in a first direction and a second generally cylindricalaperture extending through the clamp assembly in a second direction whenthe two grips are secured together.

In the representative embodiment of the clamp assembly 10 illustratedherein, the first generally cylindrical split aperture 44 can be sizedto received a tubular beam 92 that is about three inches in diameter, asshown in FIGS. 1 and 6, while the second generally cylindrical splitaperture 46 can be sized to received a tubular beam 94 that is about twoand a half inches in diameter (FIGS. 7 and 8). In both cases, the firstcurved surface 40 and second curved surface 42 can be shaped tosubstantially conform to rounded sides of the tubular beam. In otherwords, the first curved surfaces 40 and second curved surfaces 42 canhave the same radius of curvature as the tubular beam they are intendedto clamp around. This configuration can result in a relatively large anddispersed contact surface that extends across the interior faces of thefirst and second grips 20, 30, and that can provide a large, uninformand stable clamping force that secures the clamp assembly 10 to thetubular beam.

Nevertheless, the generally cylindrical split apertures 44, 44 of theclamp assembly 10 may not be limited to clamping around tubular beams ormembers having a radius of curvature that substantially matches theradius of curvature of the curved surfaces formed into the inside facesof the fingers. In some aspects, the clamp assembly 10 can also providesufficient clamping force to secure the clamp assembly 10 to a tubularbeam having a radius of curvature that is nominally smaller than theradius of curvature of the curved surfaces. For example, as shown inFIGS. 9-10, the clamp assembly 10 can be mounted around a tubular beam96 having a diameter of about two inches and a radius of about one inch,and that is smaller than the one and a quarter inch radius of curvatureof the curved surfaces 42 and partial cylindrical surfaces 43 that formthe split aperture 46 with a two and a half inch diameter. Nevertheless,by shortening the distance between the second planes 29, 39 to a gap 86that is smaller than the gap 84 in the same split aperture 46 clampedaround a “full-sized” tubular beam 94 (as shown in FIG. 8), much of theextra spacing can be removed and sufficient contact area between thetubular beam 96 and the two grips 20, 30 have be provided to secure theclamp assembly 10 to the smaller tubular beam 96.

The invention has been described in terms of preferred embodiments andmethodologies considered by the inventors to represent the best mode ofcarrying out the invention. However, a wide variety of additions,deletions, and modification might well be made to the illustratedembodiments by skilled artisans without departing from the spirit andscope of the invention. For example, while the base material of theclamp and flanges can generally comprise a lightweight aluminum alloy,the primary structural components of the clamp assembly can also be madefrom various other metal alloys or non-metal materials, such asplastics, thermoplastics, fiber-embedded composites, and the like.Similarly, the inside faces of the fingers and central portions maycomprise exposed base material or a base material covered with a lightcoating, such as paint, while in other aspects the interior faces can becoated with a gasket material or comparable compliant layer that canenhance the grip of the clamp assembly around the tubular beam and/orprotect the surfaces of the tubular beam from scratches ormetal-on-metal corrosion. These and other revisions might be made bythose of skill in the art without departing from the spirit and scope ofthe invention that is constrained only by the following claims.

What is claimed is:
 1. A clamp assembly configured to be clamped arounda tubular beam to provide a mounting location for an auxiliarycomponent, the clamp assembly comprising: a first grip having a centralportion and at least four separate curved fingers projecting radiallyfrom the central portion and curving generally in the same axialdirection to respective distal ends; a second grip having a centralportion and at least four separate curved fingers projecting radiallyfrom the central portion and curving generally in the same axialdirection to respective distal ends; a fastener for securing the firstand second grips together in a complementary relationship with thedistal ends of the fingers of the first grip aligning with the distalends of the fingers of the second grip; the grips, when securedtogether, defining a first split aperture extending through the fingersin a first direction and a second split aperture extending through thefingers in a second direction; the first split aperture having adiameter that substantially corresponds to the diameter of the tubularbeam to which the clamp assembly is to be clamped; and a flange mountedto one of the grips and being configured to receive the auxiliarycomponent.
 2. The clamp assembly of claim 1, wherein the first splitaperture is smaller than the second split aperture.
 3. The clampassembly of claim 2, wherein the first split aperture is sized to securethe clamp assembly to tubular beams having a diameter between about 2inches and about 2.5 inches.
 4. The clamp assembly of claim 2, whereinthe second split aperture is sized to secure the clamp assembly totubular beams having a diameter of about 3 inches.
 5. The clamp assemblyof claim 1, wherein the first split aperture and the second splitaperture are orthogonal to each other.
 6. The clamp assembly of claim 1,wherein an inside face of each finger is coated with a compliant gasketmaterial.
 7. The clamp assembly of claim 1, wherein the flange isadjustably coupled to the central portion of one of the first and secondgrips.
 8. The clamp assembly of claim 7, wherein the flange isadjustably coupled to one of the first and second grips in one of aplurality of angular positions.
 9. The clamp assembly of claim 1,wherein the fastener further comprises a machine screw having a threadedportion and a head portion.
 10. The clamp assembly of claim 9, furthercomprising: threaded holes at the distal ends of the first grip forthreaded engagement with the threaded portion of the machine screw; andnon-threaded rabbet holes at the distal ends of the second grip forreceiving the head portion of the machine screw.
 11. The clamp assemblyof claim 1, wherein the first and second split apertures are non-round.12. A clamp assembly for attachment to a tubular beams, the clampassembly comprising: a first grip and a second grip, each of the firstand second grips including a central portion defining a first plane, anda plurality of angularly-spaced separate fingers projecting radiallyoutward and curving out-of-plane from the central portion to distal endsdefining a second plane that is spaced from the first plane; each fingerhaving an inside face comprising two curved surfaces separated by acenter edge, each curved surface extending in opposite directions to aninside face of an adjacent finger, the curved surfaces together forminga plurality of partial cylindrical surfaces; and a plurality of fastenerassemblies extending between and coupling the distal ends of the fingersof the first and second grips, wherein complimentary sets of the partialcylindrical surfaces align to form split apertures sized and shaped toreceive at least one of a plurality of differently-sized tubular beamswhen the distal ends of the first and second grips are coupled together,and to clamp around and secure the clamp assembly to the tubular beam.13. The clamp assembly of claim 12, wherein one of the split aperturesis sized to secure the clamp assembly to tubular beams having a diameterbetween about 2 inches and about 2.5 inches.
 14. The clamp assembly ofclaim 12, wherein one of the split apertures is sized to secure theclamp assembly to tubular beams having a diameter of about 3 inches. 15.The clamp assembly of claim 12, wherein the plurality of partialcylindrical surfaces are orthogonal to each other.
 16. The clampassembly of claim 12, wherein the second planes of the first and secondgrips are substantially parallel to and spaced from each other.
 17. Theclamp assembly of claim 12, wherein the inside face of each finger iscoated with a compliant gasket material.
 18. The clamp assembly of claim12, further comprising a flange coupled to one of the first and secondgrips and configured to receive and mount auxiliary equipment to theclamp assembly.
 19. The clamp assembly of claim 18, wherein the flangeis coupled to the central portion of one of the first and second grips.20. The clamp assembly of claim 19, wherein the flange is configured forangular adjustment between a plurality of angular positions.
 21. Theclamp assembly of claim 12, wherein each of the fastener assembliesfurther comprises: a machine screw having a threaded portion and a headportion; and at least one jam nut threadably installed on the threadedportion of the machine screw.
 22. The clamp assembly of claim 21,further comprising: threaded holes at the distal ends of the first gripfor threaded engagement with the threaded portion of the machine screw;and non-threaded rabbet holes at the distal ends of the second grip forreceiving the head portion of the machine screws.
 23. A clamp assemblyconfigured to be clamped around a tubular beam to provide a mountinglocation for an auxiliary component, the clamp assembly comprising: afirst grip having a central portion with at least four separate curvedfingers projecting radially from the central portion, each finger havingan inside face with two curved surfaces separated by center edges, thecenter edges of the first grip extending radially from a center axis andcurving generally in the same axial direction toward respectiveattachment portions formed into distal ends of the fingers of the firstgrip; a second grip having a central portion with at least four separatecurved fingers projecting radially from the central portion, each fingerhaving an inside face with two curved surfaces separated by centeredges, the center edges of the second grip extending radially from acenter axis and curving generally in the same axial direction towardrespective attachment portions formed into distal ends of the fingers ofthe second grip; a fastener for securing the first and second gripstogether in a complementary relationship with the attachment portions ofthe first grip aligning with the attachment portions of the second grip;the curved surfaces, when the grips are secured together, defining afirst generally cylindrical split aperture extending through the clampassembly in a first direction and a second generally cylindrical splitaperture extending through the clamp assembly in a second direction; thefirst generally cylindrical split aperture having a diameter thatsubstantially corresponds to the diameter of the tubular beam to whichthe clamp assembly is to be clamped; and a flange mounted to one of thegrips and being configured to receive the auxiliary component.
 24. Theclamp assembly of claim 23, wherein the center edges of the first gripmirror the center edges of the second grip.
 25. The clamp assembly ofclaim 23, wherein the first generally cylindrical split aperture issmaller than the second generally cylindrical split aperture.
 26. Amethod of moving a clamp assembly between a plurality ofdifferently-sized tubular beams, the method comprising: uncoupling apair of grips of the clamp assembly that are clamped around a firsttubular beam having a first size, each of the grips including: a centralportion and at least four separate fingers curving radially from thecentral portion and curving generally in the same axial direction torespective distal ends; and each finger including an inside face withtwo curved surfaces separated by a center edge, with the curved surfacesextending in opposite directions to the inside faces of adjacent fingersto form a plurality of partial cylindrical surfaces, wherein a first setof partial cylindrical surfaces of the grips align to form a first splitaperture sized and shaped to receive the first tubular beam when thedistal ends of the grips are coupled together; removing the grips fromaround the first tubular beam; moving the clamp assembly to a secondtubular beam having a second size that is different from the first size;positioning a second set of partial cylindrical surfaces of the gripsaround the second tubular beam, the second set of partial cylindricalsurfaces aligning to form a second split aperture sized and shaped toreceive the second tubular beam; and coupling together the distal endsof the grips to clamp and secure the clamp assembly to the secondtubular beam.
 27. The method of claim 26, further comprising:disengaging a flange mounted to one of the first and second grips infirst angular position relative to the clamp assembly; rotating theflange; and re-engaging the flange to the grip in a second angularposition that is different from the first angular position.